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Euglenid

Euglenids are a diverse of mostly unicellular, biflagellated protists within the phylum , belonging to the supergroup , renowned for their flexible outer that enables characteristic euglenoid movement (metaboly) and a nutritional versatility encompassing autotrophy via secondary green plastids, heterotrophy through or osmotrophy, and mixotrophy. Comprising around 1,000 to 3,000 described species, they are predominantly free-living inhabitants of freshwater ecosystems, though some occur in or environments, and a few exhibit parasitic lifestyles. The most iconic genus, , exemplifies their adaptability, thriving in nutrient-rich ponds and capable of surviving in both light and dark conditions by switching metabolic modes. In classification, euglenids form the order Euglenida, one of three primary lineages in alongside the parasitic kinetoplastids (e.g., trypanosomes) and marine diplonemids, with phylogenetic analyses based on 18S rRNA and multigene data placing them as a monophyletic group defined by synapomorphies such as a of overlapping protein strips and extrusomes for feeding or . Within Euglenida, phototrophic species are classified under the class Euglenophyceae, featuring secondary s acquired via endosymbiosis with a green alga, while heterotrophic forms fall into groups like the Rhabdomonadales or Peranemales; this division reflects their evolutionary history, with plastid acquisition occurring after divergence from other euglenozoans. Recent taxonomic revisions, such as those in the 2019 International Society of Protistologists' guidelines, emphasize molecular markers to resolve polyphyletic genera and uncover cryptic diversity. Key morphological and physiological characteristics distinguish euglenids from other protists, including a striated composed of and proteins that provides rigidity yet flexibility for gliding or wriggling motion, two flagella (one emergent and motile, the other often rudimentary and sensory) emerging from a ventral pocket, and discoid cristae in their mitochondria. Photosynthetic euglenids possess chloroplasts bounded by three membranes, containing chlorophylls a and b along with unique , and store energy as paramylon (a β-1,3-glucan) in cytoplasmic granules rather than . Heterotrophic species lack plastids but retain the ability to engulf prey via a or absorb dissolved organics, showcasing metabolic flexibility that includes unusual pathways like wax ester under conditions in species such as . Reproduction is primarily via longitudinal , with no confirmed sexual cycles, though genetic exchange may occur in some taxa. Ecologically, euglenids play vital roles as primary producers, bacterivores, and decomposers in microbial communities, often dominating in eutrophic waters where they can form dense blooms—such as red tides caused by Euglena sanguinea that produce ichthyotoxic compounds. Their resilience to environmental stressors, including low oxygen, high , and , positions them as indicators of and key players in nutrient cycling; for instance, E. gracilis is employed in wastewater bioremediation due to its ability to accumulate . Beyond ecology, euglenids hold biotechnological promise, with their lipid-rich targeted for production and high-value compounds like paramylon explored for pharmaceuticals.

Taxonomy and Classification

Historical Classification

The classification of euglenids began in the early with the work of Christian Gottfried Ehrenberg, who in 1830 described the genus and placed it among the , a group of microscopic organisms often associated with protozoan-like forms found in infusions. Ehrenberg's descriptions highlighted the flagellated, green-colored cells of , initially linking them to both algal and protozoan characteristics due to their motility and pigmentation, though his short-lived classification system emphasized their infusorial nature. Throughout the , debates persisted over the animal or affinities of euglenids, fueled by their mix of heterotrophic and photosynthetic traits, leading to inconsistent placements in either zoological or botanical schemes. This ambiguity was resolved in part by in 1866, who introduced the kingdom Protista to encompass all unicellular organisms, including euglenids, as primitive forms bridging and animal kingdoms. In the early 20th century, taxonomic efforts advanced with Bütschli's 1884 establishment of the Euglenida as a group of flagellates based on their and flagellar structure. Pascher's proposal of the class Euglenophyceae within the division emphasized their algal affinities, particularly for photosynthetic forms, influencing botanical classifications. Later, Hollande in 1942 divided euglenids into three groups based on structural features: Peranemoidées (flexible phagotrophs), Petalomonadinées (rigid phagotrophs), and Euglenidinées (rigid osmotrophs and phototrophs), reflecting distinctions in , flexibility, and . These mid-20th-century revisions up to the 1980s, including integrations into broader protozoan systems, highlighted ongoing shifts toward recognizing euglenids' dual plant-animal heritage, though later molecular phylogenies have confirmed the of many such older groupings.

Current Taxonomy

Euglenids are classified within the domain Eukaryota, clade Discoba, phylum Euglenozoa, and class Euglenida, encompassing approximately 1,500 described species of unicellular flagellates with diverse nutritional modes. The class Euglenida is divided into major groups based on molecular phylogenies and morphological traits, including the photosynthetic clade Euglenophyceae (approximately 800 species, primarily freshwater forms with secondary green plastids), the flexible Spirocuta (phagotrophic lineages such as Heteronematales and Rhabdomonadales, featuring metaboly via numerous pellicular strips), and the basal, rigid Petalomonadida (armored, gliding forms with fewer pellicular strips). Recent molecular studies have revised euglenid taxonomy, with Lax et al. (2020) establishing Spirocuta as a novel clade that includes about 40% of euglenid diversity, encompassing flexible phagotrophs alongside their photosynthetic and osmotrophic relatives; subsequent work by Lax et al. (2023) has further resolved the backbone phylogeny using single-cell transcriptomics, introducing subgroups like Karavia and Alistosa while highlighting unresolved taxa such as Olkasia (formerly in Ploeotia) and indicating gaps in orders like Olisthomantales. Euglenid species diversity is dominated by free-living forms in aquatic environments, whereas parasitic representatives like Trypanoplasma (a pathogen) belong to the related class Kinetoplastida within the same . Historical groupings such as Phytomonadina, based on outdated morphological criteria, have been superseded by these phylogenetically informed classifications.

Phylogenetic Relationships

Euglenids belong to the Euglenozoa within the larger Discoba, which encompasses diverse protists including jakobids, heteroloboseans, and Tsukubamonadida. Within Euglenozoa, euglenids (Euglenida) form a monophyletic group sister to (including trypanosomes) and Diplonemida, with Symbiontida often positioned as an early-diverging lineage. This arrangement reflects the deep splits characteristic of euglenozoan evolution, where euglenids diverged early from their parasitic and deep-sea relatives. Molecular evidence supporting these relationships derives primarily from analyses of small subunit () genes and multi-gene phylogenomics. phylogenies consistently recover as , with robust bootstrap support for the sister-group status of Euglenida to + Diplonemida. More recent phylogenomic studies using 20–125 protein-coding genes from single-cell transcriptomes have reinforced this topology, resolving previously ambiguous deep nodes and confirming the monophyly of within Discoba. These datasets highlight the utility of transcriptomic approaches in overcoming limitations of , such as long-branch attraction artifacts in early-diverging lineages. Euglenozoans show affinities to other discobans like jakobids and heteroloboseans, forming a characterized by ventral feeding grooves and modified mitochondrial cristae, though euglenids lack the latter. Despite possessing secondary plastids acquired from a via endosymbiosis, euglenids exhibit no close phylogenetic relationship to core (Chlorophyta) or other photosynthetic protists, underscoring the independent evolutionary trajectory of their plastid-bearing lineage. This secondary acquisition event, dated to around 800–1000 million years ago, positions euglenids as a key example of integration in non-archaeplastid hosts. The phylogenetic placement of euglenids illuminates broader patterns in protist evolution, particularly within Discoba (formerly ), where they serve as models for studying excavate-like feeding mechanisms and mitochondrial diversity without the complications of seen in kinetoplastids. Their highlights the mosaic nature of eukaryotic supergroups, with euglenozoans bridging heterotrophic and photosynthetic lifestyles through ancient endosymbioses, informing reconstructions of early eukaryotic diversification.

Morphology

Overall Cell Structure

Euglenids are unicellular eukaryotes belonging to the supergroup, typically measuring 15–500 μm in length and exhibiting elongated, ovoid, or spindle-shaped forms that allow for flexibility and metabolic movement. Unlike many protists, they lack a rigid and are enclosed by a flexible plasma membrane that provides the outer boundary of the . This membrane is reinforced by an underlying composed of proteinaceous strips, enabling the to maintain shape while permitting deformation. Most euglenids possess one or two flagella that emerge from an anterior , also known as the gullet or , which serves as an of the plasma membrane for flagellar insertion and feeding in some species. In phototactic species, such as many photosynthetic forms, an eyespot or —a pigmented, lens-like structure composed of granules—is located near the base of the emergent to detect light direction and facilitate phototaxis. The of euglenids is differentiated into an outer ectoplasm, a gel-like layer associated with the and involved in , and an inner , a more fluid region containing organelles and metabolic activities. Energy reserves are stored as paramylon granules, which are insoluble β-1,3-glucan polymers distributed throughout the and serving as the primary storage compound. Freshwater euglenids typically feature a contractile located near the anterior , which periodically expels excess water to maintain osmotic balance in hypotonic environments.

Pellicle and

The of euglenids forms a dynamic cortical underlying the , composed of overlapping longitudinal proteinaceous strips made primarily of epiplasmic articulins, which are underlain by articulating typically arranged in sets of four per strip. These strips interlock via junction zones with cross-bridges and nanotubules, often helically oriented, providing while permitting flexibility. This composition enables euglenoid , or metaboly, through calcium-dependent contractions of centrin fibers that drive deformations between strips, allowing up to 340% relative sliding and resulting in peristaltic undulations for propulsion. Euglenids exhibit diverse flagellar arrangements that complement pellicle-based motility, with most species possessing two flagella emerging from an anterior : a prominent anterior () flagellum bearing mastigonemes—hair-like appendages that enhance hydrodynamic drag and generate propulsive thrust through undulatory waves—and a shorter posterior (ventral) flagellum, often reduced to a , which facilitates steering or substrate contact for . In heterotrophic forms, the posterior flagellum may contribute to directed along surfaces, while the anterior flagellum's mastigonemes enable efficient forward propulsion in fluid environments. can also occur via coordinated pellicle undulations, independent of flagellar beating in some cases. Locomotion in euglenids encompasses multiple modes adapted to their environments: flagellar swimming, where the anterior propels the cell at speeds up to 50 times faster than metaboly in open water; crawling through euglenoid motion, involving traveling waves of deformation at frequencies around 0.1 Hz for slow, substrate-oriented progression; and amoeboid crawling in non-flagellate forms, relying on localized and flexibility to extend pseudopod-like protrusions. These mechanisms allow euglenids to navigate varied microhabitats, from planktonic to benthic. Pellicle rigidity varies across euglenid groups, influencing locomotor capabilities; for instance, the pellicle in Euglena species is flexible, supporting pronounced metaboly via strip sliding, whereas in Phacus it is more rigid due to fused or tightly interlocked strips, restricting shape changes but enhancing streamlined swimming. Such adaptations correlate with nutritional modes and habitats, with flexible pellicles prevalent in photosynthetic or osmotrophic forms and rigid ones in phagotrophic lineages.

Organelles

Euglenids possess a single, large that is typically spherical or ovoid, bounded by a typical eukaryotic with pores, and characterized by a conspicuous subcentral that persists throughout the . The within the appears permanently condensed, forming distinct patches or lumps visible under light microscopy and appearing electron-dense in transmission electron micrographs, which contributes to the 's lumpy appearance. This condensed arrangement is a hallmark feature distinguishing euglenid nuclei from those of many other protists. Mitochondria in euglenids are typically single and large, often forming a reticulated network throughout the , with a distinctive discoidal cristae where the inner folds into stalked, paddle-shaped structures. This cristae configuration is a defining trait of the supergroup and supports efficient energy production in these versatile protists. Although some euglenids exhibit organized in nucleoids that resemble kinetoplast-like structures in complexity, these are structurally distinct from the true kinetoplast DNA found in kinetoplastids, lacking the interlocked minicircle-maxicircle network. The Golgi apparatus in euglenids consists of numerous dictyosomes, each comprising stacks of 15–30 cisternae, and is particularly elaborate, often concentrated near the anterior region of the cell close to the flagellar reservoir. These dictyosomes play a key role in the secretion of , with cisternae dilating to accumulate and package the material before release, aiding in cell protection and locomotion. The in euglenids is prominent, featuring extensive () cisternae that lie parallel to the and support the underlying strips, facilitating intracellular and dynamics. In phagotrophic , this system includes the feeding apparatus, known as the rod-organ or , which comprises microtubule-reinforced and curved vanes forming a complex cytoskeletal structure for prey capture and ingestion. The , often two in number, provide rigidity, while the vanes enable the engulfment of food particles into a cytopharynx. Contractile vacuoles, integral to , are typically positioned near the flagellar reservoir and connect to it via a .

Ecology and Nutrition

Habitats and Distribution

Euglenids are predominantly inhabitants of freshwater environments, including ponds, rivers, lakes, and wetlands, where they thrive in nutrient-rich, eutrophic conditions often associated with high organic matter content. These protists are commonly found in shallow, stagnant waters such as marshes and oxbow lakes, as well as in moist soils and sediments. For instance, species like Euglena and Phacus are frequently observed in these settings, contributing to the microbial communities in temperate and tropical freshwater systems. While primarily freshwater dwellers, euglenids also occur in marine and brackish habitats, though less commonly, with genera such as Eutreptiella adapted to coastal and estuarine environments. Some species tolerate extreme conditions, including acidic bogs, sites, and heavy metal-contaminated waters; for example, Euglena mutabilis persists in low-pH, metal-rich biotopes. Terrestrial occurrences are limited to damp soils and leaf litter, but these are not primary niches. Euglenids exhibit a , reported across all continents in both temperate and tropical regions, with records from diverse locales including the , , , , and . Highest species diversity is documented in eutrophic wetlands and small water bodies, particularly in temperate zones where studies have revealed rich assemblages. Tropical areas, however, harbor significant undescribed diversity, potentially comprising a substantial portion of the group's estimated 1,000–3,000 known species. Certain euglenids form symbiotic or parasitic associations with , such as Colacium species epibiontic on or Michajlowastasia infecting larvae. Their abundance is notably influenced by environmental factors, with blooms occurring in eutrophic waters under optimal conditions of 20–30°C, neutral to slightly alkaline (6.5–7.0), and elevated nutrients like and . Light availability further promotes population growth in photosynthetic forms, leading to dense aggregations, such as those of Euglena sanguinea in nutrient-polluted ponds. Recent studies have identified toxin production, such as euglenophycin, in at least six euglenoid , contributing to bloom toxicity and ecological dynamics.

Nutritional Modes

Euglenids display a range of non-photosynthetic nutritional strategies that enable them to thrive in diverse aquatic environments, primarily through phagotrophy and osmotrophy, with some species exhibiting mixotrophic combinations of these modes. These heterotrophic approaches are particularly prevalent among colorless euglenids, which lack chloroplasts and rely on external for sustenance. While represents an alternative autotrophic mode in other euglenids, the focus here is on these absorptive and ingestive mechanisms. Phagotrophy is a key feeding strategy in many euglenids, involving the active engulfment of prey particles such as , , or other protists through a specialized oral apparatus. This process occurs via the , a mouth-like opening at the anterior end, often supported by a rod-organ composed of extrusomes and that aids in prey capture and . For instance, Peranema trichophorum exemplifies this mode by using its rod-organ to pierce and extract contents from larger prey like eukaryotic or to engulf smaller , demonstrating both myzocytotic (partial externally) and holophagic (whole ) capabilities. Once internalized, prey is enclosed in food vacuoles where enzymatic breakdown occurs, releasing nutrients for absorption. In contrast, osmotrophy allows euglenids to directly absorb dissolved organic compounds from the surrounding medium across the plasma membrane, bypassing the need for ingestion. This mode is common in non-phagotrophic, colorless species adapted to nutrient-rich, organic-laden waters, such as Astasia longa, which primarily utilizes , sugars, and other solutes for growth. Osmotrophic euglenids often possess a thin, permeable that facilitates this passive uptake, enabling survival in low-particle environments where phagotrophy would be inefficient. Some euglenids employ mixotrophy by combining phagotrophy and osmotrophy, allowing flexibility in acquisition depending on environmental availability, as seen in certain heterotrophic lineages that switch between ingesting particles and absorbing solubles. The evolutionary origin of osmotrophy in euglenids remains unclear, with phylogenetic analyses suggesting it arose independently or through transitions from phagotrophic ancestors in multiple lineages, though the precise selective pressures driving this shift are not fully resolved in recent reviews. Nutritional adaptations in these euglenids include the formation of food vacuoles for , where acid hydrolases and other enzymes break down engulfed material without the presence of true lysosomes typical of metazoans; instead, vacuolar acidification and enzymatic action handle and release. This system supports efficient recycling of cellular components and adaptation to fluctuating resource levels in freshwater and marine habitats.

Photosynthetic Euglenids

Photosynthetic euglenids, primarily within the class Euglenophyceae, possess secondary plastids acquired through an ancient endosymbiotic event involving a closely related to the extant prasinophyte genus Pyramimonas. This secondary endosymbiosis resulted in plastids surrounded by three membranes, distinguishing them from primary plastids in . The Euglenophyceae represent the main photosynthetic subgroup among euglenids, with most of the approximately 3,000 described euglenid exhibiting phototrophy, though some retain the ability to switch to heterotrophic modes under varying environmental conditions. The chloroplasts of Euglenophyceae contain chlorophylls a and b, enabling harvesting similar to that in green plants and algae, with thylakoids arranged in stacks of three lacking a . Energy reserves from are stored as paramylon, a β-1,3-glucan deposited in the outside the plastids, which serves as a primary storage compound. Phototaxis is facilitated by an , consisting of carotenoid-rich globules that act as a -shielding structure to direct the cell's movement toward optimal conditions via the paraflagellar swelling on the emergent . This eyespot, composed mainly of and other , is essential for positive phototaxis and orientation in photosynthetic species. A prominent example is Euglena gracilis, widely used as a model organism in research due to its robust photosynthetic capabilities and metabolic versatility, particularly for lipid production under stress conditions such as nutrient limitation or darkness, yielding high levels of wax esters and polyunsaturated fatty acids like arachidonic acid. Additionally, E. gracilis synthesizes vitamins such as ascorbic acid (vitamin C) from glucose via a unique pathway and β-carotene (provitamin A), highlighting its biotechnological potential for nutritional supplements. In natural settings, photosynthetic euglenids function as primary producers in freshwater ecosystems, contributing significantly to phytoplankton biomass and oxygen production while occasionally forming dense blooms in nutrient-enriched waters like ponds and lakes. These blooms, often dominated by species like Euglena and Phacus, can alter water quality but underscore their role in aquatic food webs.

Reproduction

Asexual Reproduction

Asexual reproduction in euglenids occurs primarily through binary , a process that enables rapid propagation under favorable environmental conditions. This longitudinal division begins with the replication of cellular components, including the undergoing , followed by duplication of the flagella, gullet (), and eyespot (). The mitotic forms intranuclearly, with originating from dense plaques on the ; during , kinetochores interact with through the intact , and daughter nuclei form via envelope constriction. proceeds by furrowing that initiates anteriorly between the flagella and migrates posteriorly, resulting in two identical daughter cells that reform the structure for flexibility and locomotion. Atypical cell divisions, producing more than two daughter cells, have also been observed in some euglenids under specific conditions. No confirmed has been observed, making binary the sole verified reproductive mode. The euglenid cell cycle aligns with standard eukaryotic patterns, where DNA replication during the S-phase precedes , leading to genome duplication and progression to G2. follows, ensuring equitable distribution of replicated DNA to daughter nuclei, with completing the division through cytoplasmic furrowing that separates the cell into two viable offspring. This coordinated sequence supports efficient population growth without meiotic processes. In response to adverse conditions such as or scarcity, euglenids form temporary resting cysts or palmelloid stages in some species, which serve as a dormant mechanism. Encystment involves the secreting a protective , reducing metabolic activity to withstand . Excystment is triggered by favorable cues like and availability, allowing the to resume and binary fission. Under optimal conditions, such as 25-30°C and adequate light/nutrients, Euglena gracilis exhibits rapid division rates, with generation times typically ranging from 12 to 24 hours in laboratory cultures, facilitating quick adaptation to dynamic aquatic habitats.

Evidence for Sexual Reproduction

Euglenids are predominantly regarded as asexual organisms, with no definitive observations of gametes, zygotes, or meiotic divisions reported across the group. Reproduction relies on binary fission, and the absence of confirmed sexual processes has led to classifications emphasizing parthenogenesis-like mechanisms without genetic recombination. Early 20th-century reports suggested sexual phenomena, such as and formation in species, as described by Biecheler in 1937, who observed isogamous unions but could not confirm . Similar claims emerged for conjugation in during , but these were later dismissed as observational artifacts or misinterpretations of vegetative division. Additional accounts, including Leedale's 1962 cytological evidence of potential in Hyalophacus ocellatus and Mignot's 1962 description of in Scytomonas, remain unverified and controversial, with modern reviews attributing them to atypical rather than true sexuality. Rosowski's 2003 analysis concluded that only mitotic is reliably documented in euglenoids. Genomic investigations provide indirect hints of sexual potential, particularly through the identification of conserved meiotic genes in Euglena gracilis, such as SPO11, DMC1, HOP2 (with multiple copies), MND1, MSH4, and MSH5, which facilitate recombination and homolog pairing. These genes, detected in transcriptome and draft genome assemblies, suggest latent machinery for meiosis, though their constitutive expression may not strictly indicate active sexual cycles, as seen in other asexual protists. Hypotheses of cyst fusion or rare genetic exchange remain untested, with no population-level evidence of recombination driving diversity. Significant research gaps persist, including the lack of to detect rare meiotic events or variations, which could clarify if sexuality occurs under specific environmental stresses. and have been proposed to identify fusion or chromosome pairing, but comprehensive studies are needed to resolve these uncertainties.

Evolution

Evolutionary Origins

Euglenids represent an ancient lineage within the eukaryotic diversification that occurred during the era, with evidence suggesting their origins may trace back as early as 2 billion years ago as part of the initial radiation of protists. This early emergence aligns with the broader development of complex eukaryotic cells, including the acquisition of flagellar apparatus for , a trait shared with their excavate-like ancestor characterized by a ventral feeding groove and associated cytoskeletal structures. The , encompassing euglenids, diverged early from other lineages within the Discoba supergroup (formerly part of ), retaining flagellar traits such as the flagellar pocket while some euglenids exhibit a loss of the typical excavate feeding groove, adapting to alternative feeding strategies. A pivotal innovation in euglenid was the development of the , a flexible proteinaceous strip system underlying the plasma membrane that enables characteristic euglenoid movement and shape changes. Ancestral euglenids likely possessed a simple with 10 or fewer longitudinal strips, which evolved into more complex helical arrangements with increased strip numbers (e.g., 18–20) in derived clades, enhancing flexibility and facilitating transitions from rigid to deformable cell forms. This structural advancement supported shifts in nutritional modes, from ancestral phagotrophy to osmotrophy in many free-living species, allowing efficient absorption of dissolved nutrients in diverse aquatic environments. Genomic studies reveal insights into these evolutionary adaptations, highlighting extensive lateral gene transfer from that contributed to metabolic versatility in euglenids. For instance, genes involved in pathways like have bacterial origins, aiding in the diversification of energy metabolism. Recent advances in euglenoid as of 2024 have provided new assemblies of and genomes, illuminating patterns of proliferation and gene reorganization that underpin their ancient divergence and persistence. Euglenid genomes, while varying in size (e.g., approximately 500 Mb in ), show streamlined features in some lineages that correlate with specialized lifestyles, underscoring the role of gene acquisition and reorganization in their ancient divergence and persistence.

Fossil Record

The fossil record of euglenids remains sparse due to their predominantly soft-bodied , which resists fossilization in most sedimentary contexts, though recent reinterpretations have expanded recognized occurrences. The oldest unequivocal evidence of euglenids consists of Moyeria-like forms from Late to deposits, dating to approximately 450–420 million years ago; these microfossils were confirmed as euglenids through detailed analysis of their and associated biomarkers, revealing helical striations analogous to those in modern euglenid cell walls. A 2024 palynological study has further identified euglenoid cysts in , , and Permian deposits, extending the record through the and indicating a more persistent presence in ancient freshwater environments than previously appreciated. Mesozoic records include cyst-like structures preserved in amber and sediments, such as Pseudoschizaea forms from the Triassic-Jurassic boundary (~200 million years ago) in European localities like , the , and ; these 20–30 micrometer cysts exhibit wall ultrastructures matching encysted stages of extant photosynthetic euglenids, with similar forms now recognized from earlier strata. Preservation challenges have necessitated integration with analyses, which estimate the crown-group radiation of euglenids (and broader ) between approximately 600 and 800 million years ago, predating the oldest fossils and highlighting a protracted . Collectively, these findings underscore euglenids' early diversification and colonization of freshwater habitats during the , aligning with their modern ecological dominance in lentic environments.

Plastid Evolution

The plastids of euglenids originated through secondary endosymbiosis, in which a phagotrophic euglenid ancestor engulfed a green alga related to the prasinophyte genus Pyramimonas, establishing a photosynthetic bounded by three membranes. Unlike some other secondary plastids, such as those in cryptophytes, euglenid lack a nucleomorph, indicating complete integration of the endosymbiont's into the host genome early in the process. This endosymbiotic event is estimated to have occurred between approximately 652 and 539 million years ago, during the period, based on analyses of euglenid and algal phylogenies as of 2024. Following endosymbiosis, extensive endosymbiotic gene transfer (EGT) relocated the majority of genes from the algal endosymbiont's genome to the euglenid host nucleus, facilitating control over plastid function. Roughly 90% of the original algal nuclear genes associated with plastid metabolism and maintenance were transferred, with the plastid genome retaining a reduced set of around 100 genes, primarily encoding proteins for photosynthesis, transcription, and translation. This gene relocation underscores the evolutionary mechanism by which host cells co-opt endosymbiont capabilities, as evidenced by nuclear-encoded plastid-targeted proteins in modern euglenids like Euglena gracilis. Recent genomic studies have detailed the convoluted history of plastid genome structure in euglenids, including expansions of group II and III introns that reflect ongoing evolutionary dynamics post-endosymbiosis. Plastids are present in only about 30% of euglenid species, primarily within the photosynthetic Euglenophyceae, with secondary losses occurring multiple times in non-photosynthetic lineages due to shifts toward heterotrophy. These plastids contain chlorophylls a and b, along with , reflecting their green algal heritage, though some species exhibit pigment variations adapted to diverse environments. The evolutionary history of euglenid plastids serves as a key model for understanding integration in eukaryotes, highlighting convergent patterns of gene transfer and reduction across independent endosymbiotic events. Recent studies in the 2020s have illuminated the evolution of —proteinaceous structures within euglenid plastids that enhance CO₂ fixation by concentrating inorganic carbon around . Proteomic analyses reveal that pyrenoid composition in euglenids evolved independently from those in other algal lineages, involving distinct nuclear-encoded components for biogenesis and carbon concentrating mechanisms (CCMs). These findings emphasize ' role in adapting to low-CO₂ environments, providing insights into broader algal CCM evolution.

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